Abstract
In this study, processes of a liquid fuel spray ignition and heat release during its combustion were under investigation. The purpose of this study was to elucidate whether the ignition properties and heat release process of a liquid fuel injected into the environments of parameters exceeding its critical values differ from those obtained for subcritical regimes. Therefore, the fuel was injected into the environments of parameters below, around and above its critical values. The ignition and combustion processes were observed by monitoring the pressure in the combustion chamber and by using a high-speed camera through transparent piston. The ignition process was characterized by ignition delay, while the combustion process by heat release and rate of heat release. The ignition delay was determined by pressure rise according to tangential method. Ignition delay determined that way included both physical delay and chemical delay. Obtained results revealed stochastic nature of the spray ignition of n-hexane. No major difference in ignition delay in terms of exceeding critical parameters was noticed. The only parameter directly influencing the ignition delay was the injectant initial temperature.
Highlights
Spray combustion appears in a broad variety of power systems, such as furnaces, industrial burners, gas turbines and reciprocating engines
The purpose of this study was to elucidate whether the ignition properties and heat release process of a liquid fuel injected into the environments of parameters exceeding its critical values differ from those obtained for subcritical regimes
The study of the autoignition process of n-hexane occurring after the injection was conducted in a rapid compression machine (RCM) at Poznan University of Technology
Summary
Spray combustion appears in a broad variety of power systems, such as furnaces, industrial burners, gas turbines and reciprocating engines. The engine performance, emissions and energy conversion efficiency are directly dependent on the quality of spray combustion. Spray combustion concerned only CI (compression ignition) engines. Since direct injection was applied to SI (spark ignition) engines, it concerns both types of engines. In CI engines, the start of combustion is controlled by the injection of the fuel. A reliable and predictable autoignition is required. In SI engines, in turn, where the start of combustion is controlled by a spark, autoignition should be avoided. The spray autoignition and combustion characteristics of the fuel are of crucial importance
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